Leonhard Euler: quatre lIiçons escollides

L'FME dedica el curs acadèmic 2006-2007 a la figura del matemàtic suís Leonhard Euler, una de les ments més importants de la història, comparable a Gauss o Arquímedes. La lliçó inaugural va anar a càrrec d'Enric Fossas, catedràtic i director de l'Institut d'Organització i Control de Sistemes Industrials de la UPC

Leonhard Euler, Brustbild

Signatur des Originals: S 36/G00802

Leonhard Euler, Brustbild

Signatur des Originals: S 36/G00803

Leonhard Euler's Vollstandige anleitung zur differenzial-rechnung : Aus dem lateineschen ubersetzt und mit anmerkungen und zusatzen begleitet /

Bound in marbled paper boards; brown leather shelfback and corners, stamped in gold.

Euler : el maestro de todos los matemáticos.

Recorrido por la biografía del matemático suizo Leonhard Euler. El artículo se estructura en base a los diferentes periodos de la vida del científico y sus aportaciones en el mundo de las matemáticas, sobretodo en el campo del álgebra.

El problema de Basilea. El año de Euler : 1707-2007.

Se muestran algunas de las teorías del matemático Leonhard Euler..

De solutione problematum diophanteorum per números integros : o primeiro trabalho de Euler sobre equações diofantinas

The present dissertation analyses Leonhard Euler´s early mathematical work as Diophantine Equations, De solutione problematum diophanteorum per números íntegros (On the solution of Diophantine problems in integers). It was published in 1738, although it had been presented to the St Petersburg Academy of Science five years earlier. Euler solves the problem of making the general second degree expression a perfect square, i.e., he seeks the whole number solutions to the equation ax2+bx+c = y2. For this purpose, he shows how to generate new solutions from those already obtained. Accordingly, he makes a succession of substitutions equating terms and eliminating variables until the problem reduces to finding the solution of the Pell Equation. Euler erroneously assigns this type of equation to Pell. He also makes a number of restrictions to the equation ax2+bx+c = y and works on several subthemes, from incomplete equations to polygonal numbers

Euler e os números pentagonais

The present investigation includes a study of Leonhard Euler and the pentagonal numbers is his article Mirabilibus Proprietatibus Numerorum Pentagonalium - E524. After a brief review of the life and work of Euler, we analyze the mathematical concepts covered in that article as well as its historical context. For this purpose, we explain the concept of figurate numbers, showing its mode of generation, as well as its geometric and algebraic representations. Then, we present a brief history of the search for the Eulerian pentagonal number theorem, based on his correspondence on the subject with Daniel Bernoulli, Nikolaus Bernoulli, Christian Goldbach and Jean Le Rond d'Alembert. At first, Euler states the theorem, but admits that he doesn t know to prove it. Finally, in a letter to Goldbach in 1750, he presents a demonstration, which is published in E541, along with an alternative proof. The expansion of the concept of pentagonal number is then explained and justified by compare the geometric and algebraic representations of the new pentagonal numbers pentagonal numbers with those of traditional pentagonal numbers. Then we explain to the pentagonal number theorem, that is, the fact that the infinite product(1 x)(1 xx)(1 x3)(1 x4)(1 x5)(1 x6)(1 x7)... is equal to the infinite series 1 x1 x2+x5+x7 x12 x15+x22+x26 ..., where the exponents are given by the pentagonal numbers (expanded) and the sign is determined by whether as more or less as the exponent is pentagonal number (traditional or expanded). We also mention that Euler relates the pentagonal number theorem to other parts of mathematics, such as the concept of partitions, generating functions, the theory of infinite products and the sum of divisors. We end with an explanation of Euler s demonstration pentagonal number theorem

Os artigos de Euler sobre os números amigáveis

Among the many methodological resources that the mathematics teacher can use in the classroom, we can cite the History of Mathematics which has contributed to the development of activities that promotes students curiosity about mathematics and its history. In this regard, the present dissertation aims to translate and analyze, mathematically and historically, the three works of Euler about amicable numbers that were writed during the Eighteenth century with the same title: De numeris amicabilibus. These works, despite being written in 1747 when Euler lived in Berlin, were published in different times and places. The first, published in 1747 in Nova Acta Eruditorum and which received the number E100 in the Eneström index, summarizes the historical context of amicable numbers, mentions the formula 2nxy & 2nz used by his precursors and presents a table containing thirty pairs of amicable numbers. The second work, E152, was published in 1750 in Opuscula varii argument. It is the result of a comprehensive review of Euler s research on amicable numbers which resulted in a catalog containing 61 pairs, a quantity which had never been achieved by any mathematician before Euler. Finally, the third work, E798, which was published in 1849 at the Opera postuma, was probably the first among the three works, to be written by Euler

O algoritmo de Damm

(...) Recentemente, em 2004, H. Michael Damm provou na sua tese de doutoramento a existência de quase-grupos totalmente anti-simétricos para ordens diferentes de 2 e 6. A tabela da imagem define um quase-grupo totalmente anti-simétrico de ordem 10, adaptado de um exemplo apresentado por Damm na sua tese. Esta tabela é o que se designa por quadrado latino: em cada linha e em cada coluna, cada um dos símbolos utilizados devem figurar uma e uma só vez. Os quadrados latinos surgiram pelas mãos de um grande matemático, talvez o maior matemático de todos os tempos: Leonhard Euler (1707-1783). Este tipo de tabelas não é totalmente estranho ao leitor. Se olhar com atenção, encontrará apenas duas diferenças em relação aos tradicionais desafios de Sudoku: não existem as chamadas "regiões" e utiliza-se o 0, para além dos algarismos 1-9. A descoberta de Damm impulsionou o desenvolvimento de um novo algoritmo com o seu nome, que tem a vantagem de apenas utilizar os algarismos tradicionais, do 0 ao 9, e de detetar 100% dos erros singulares e 100% das transposições de algarismos adjacentes. Em relação ao algoritmo de Verhoeff, tem uma implementação mais simples e deteta 100% dos erros fonéticos (por exemplo, quando se escreve 15 em vez de 50, devido à pronúncia semelhante destes números em inglês: "fifteen" e "fifty"). Na imagem, ilustra-se um exemplo de aplicação deste algoritmo para determinar o algarismo de controlo do número 201436571? (o ponto de interrogação representa o algarismo de controlo, por enquanto, desconhecido). (...)

Complex networks and data mining: toward a new perspective for the understanding of complex systems

Complex systems, i.e. systems composed of a large set of elements interacting in a non-linear way, are constantly found all around us. In the last decades, different approaches have been proposed toward their understanding, one of the most interesting being the Complex Network perspective. This legacy of the 18th century mathematical concepts proposed by Leonhard Euler is still current, and more and more relevant in real-world problems. In recent years, it has been demonstrated that network-based representations can yield relevant knowledge about complex systems. In spite of that, several problems have been detected, mainly related to the degree of subjectivity involved in the creation and evaluation of such network structures. In this Thesis, we propose addressing these problems by means of different data mining techniques, thus obtaining a novel hybrid approximation intermingling complex networks and data mining. Results indicate that such techniques can be effectively used to i) enable the creation of novel network representations, ii) reduce the dimensionality of analyzed systems by pre-selecting the most important elements, iii) describe complex networks, and iv) assist in the analysis of different network topologies. The soundness of such approach is validated through different validation cases drawn from actual biomedical problems, e.g. the diagnosis of cancer from tissue analysis, or the study of the dynamics of the brain under different neurological disorders.